EP0162311A2 - Control circuit for a video camera, and method for controlling a video camera - Google Patents

Abstract

The present invention relates to a control circuit for a video camera, with which a charge image of an object to be recorded can be generated, which is at least partially deleted when the charge image is read out in order to generate a video output signal. The invention further relates to a method for controlling such a video camera. In order to avoid flickering of a video image generated with the video output signal when the supply of light to the video camera is periodically interrupted, reading out of the charge image of the video camera is periodically prevented at least during the period of time during which there is a supply of light from the object to be recorded to the video camera.

Description

The present invention relates to a control circuit for a video camera, with which a charge image of an object to be recorded can be generated, which is at least partially deleted when the charge image is read out in order to generate a video output signal of the video camera. Furthermore, the present invention relates to a method for controlling a video camera with the method steps of generating a charge image of an object to be recorded and generating a video output signal by reading the charge image at least partially to delete the charge image.

Video cameras with control circuits which periodically generate a charge image of an object to be recorded by means of an image converter, which can be designed as a Vidikon tube, have been known for some time. In such a known video camera, the charge image of the Vidikon tube is scanned periodically in order to generate a video output signal. When the charge pattern of the Vidikon tube is scanned in this way, the charge pattern is at least partially deleted. The control of the scanning of the charge image for generating the video output signal is carried out in the known video camera by means of vertical and horizontal synchronization signals which cause the charge image to be read out in synchronization with vertical synchronization pulses and horizontal synchronization pulses, the time interval between two successive synchronization pulses representing the readout repetition rate for the Charge image determines, depends on the television standard with which the video camera in question works.

Such a known video camera with a control circuit works extremely satisfactorily with continuous supply of light from the object to be recorded to the video camera.

However, if the known video camera is used to record an object with a periodically fluctuating or periodically interrupted light supply from the object to be recorded to the video camera, then the image of a video display device generated by means of the video output signal of the video camera has a strong flicker.

A practical case in which such problems occur is in the use of the video camera to generate a monitor signal or to produce a video tape for later film editing in a motion picture single-lens reflex film recording camera. In such a case, the video camera is arranged in a viewfinder beam path of the motion-picture reflex film recording camera, either in order to enable people other than just the cameraman to assess the currently recorded image on one or more monitors, or to support later film editing work to create a video recording running parallel to the filmed scene on a video tape, on which additional data for the film cut may be recorded. In this case, the periodic presence and absence of light from the object to be recorded to the video camera arises from the fact that a movable mirror diaphragm in the beam path of the motion-picture reflex film recording camera periodically releases the light path from the object to be recorded alternately to the film to be exposed or to Video camera arranged in the viewfinder beam path.

Based on this state of the art, it is available The invention is based on the object of developing a control circuit for a video camera according to the preamble of claim 1 and a method for controlling a video camera according to the preamble of claim 17 so that even with fluctuating, in particular periodically interrupted, light supply from the object to be recorded to the video camera, a flicker-free Video image can be generated.

This object is achieved in a control circuit with the features according to the preamble of claim 1 by the features contained in the characterizing part of this claim and in a method with the features according to the preamble of claim 17 by the features specified in the characterizing part of this claim.

The invention is based on the knowledge that in the arrangement of the known video camera described above, within a motion picture SLR film recording camera, flickering of the video image that can be generated with the video output signal of the video camera is not only caused by the fact that the mirror aperture periodically interrupts the light path to the video camera, so that pixels of the charge image recorded during corresponding times are black, but also come about because the time effective for charging a pixel of the charge image between the last erasing readout and the next erase readout of the charge image is shortened by time intervals which change from image to image, while which the light path to the video camera is interrupted. In other words, the respective time span of effective exposure for a picture element of the charge image between an erased reading out of the charge image for generating a video output signal and the next erased reading out of the charge image for generating the next video output signal differs from picture to picture, since the usual picture repetition rate of a motion picture SLR film recording camera does not match the subframe rate of a video camera. For example, the frame rate of a motion picture single-reflex film recording camera is usually 24 frames per second, while the frame rate or field frequency of a conventional video camera is 60 frames per second.

According to the invention, the image flicker is eliminated by preventing the reading of the charge image for generating the video output signal during the supply of light to the video camera, so that reading out the charge image is only possible when the supply of light to the video camera is interrupted. This has the effect that the exposure duration, which is decisive for the pixel brightness, remains constant from video field to video field. In other words, the time control for reading out the charge image for generating the video output signal is preferably carried out in such a way that the effective exposure time for each pixel corresponds to the full period of the periodic supply of light to the video camera.

For the effective exposure time of a single pixel, it is irrelevant at what point in time the reading of the charge image takes place during the period of the interrupted light supply, since the charge potential of the pixel remains constant during the period of the interrupted light supply.

The control circuit according to the invention for a video camera and the method according to the invention for controlling the video camera thus ensure a flicker-free video image regardless of the frame rate of the motion picture single-lens reflex fila camera.

In the application of the video camera within the motion picture SLR film recording camera, the length of time the light is supplied from the object to be recorded to the video camera is usually longer than the period of time that is available when the usual video clock is used to build up the charge image between two times of reading. In the example described above, this period of time with a 48th of a second is approximately 25% above the corresponding video clock period of a 60th of a second. This desirably leads to a significantly stronger exposure of the image converter of the video camera.

The development of the control circuit according to the invention specified in claim 2 enables the image memory to be read out in the usual video cycle, irrespective of the field repetition rate of the video camera which is now influenced by the mode of operation of the motion picture reflex camera. Because the transfer signal for transferring the charge image from the video camera to the image memory is only generated in the absence of light supply to the video camera, the charge image is only transferred to the image memory during its static state. The image memory can be scanned on the output side at a frequency which is independent of the field frequency of the video camera. This enables adaptation to the television standard required in each case.

The preferred further development of the control circuit according to the invention as claimed in claim 3 and the method as claimed in claim 19 ensures efficient storage, since a partial image is only transferred from the video camera to the image memory if the partial image has new image content. Furthermore, it is avoided that after a deleting takeover of a part image takes place in the image memory in a faulty manner, another partial image takeover, which would lead to an undesired deletion of the image memory content.

The respective presence and absence of light supply to the video camera can be determined in a simple manner by using a photoelectric element as described in claim 4.

Reliable information about the presence or absence of a supply of light from the object to be recorded to the video camera can be obtained in the case of the use of the video camera already described within a single-lens reflex camera by scanning the position of the mirror diaphragm of the single-lens reflex camera.

The derivation of the takeover signal for the image memory from the signal preventing the reading out of the charge image is very simple to implement in terms of circuitry.

A further increase in the image quality is achieved by the developments of the control according to the invention described in claims 7 and 8 and by the development of the method according to the invention specified in claim 20. It has been found that reading out the charge image to generate the video output signal, which, after the signal preventing the readout has ceased to exist, results in horizontal stripes in the generated video image at any point within the charge image in accordance with the current point in time within the video clock. By means of the vertical reset of the timing for the video camera in synchronization with the horizontal synchronization signal of the video camera and the output signal of the signal source, it is achieved that the reading of each charge image begins at its first pixel. The charge image is preferably also read out in synchronization with the color carrier signal in order to achieve a constant phase of the color carrier in the successive partial images.

A simple circuit implementation of the specified synchronization is achieved by the circuit specified in claim 9.

The control circuit specified in claim 10 enables the image memory content to be refreshed independently of its readout, so that a renewal of the memory content never leads to a disturbance of the image signal read out in each case.

The partial areas of the image memory are expediently switched over after a partial image has been stored.

The embodiment described in claim 12 enables the respective partial image memory contents to be read out without taking into account an atomic number or phase position of the color carrier of the partial image. It is thus possible with the configuration of the control circuit described in claim 12 to read out partial images from a partial area several times in succession in accordance with the frequency of the output-side image memory reading with respect to the frequency of storing partial images in the image memory partial areas. In the color processing circuit connected to the image memory output, the phase of the color carrier signal, which is constant from field to field, is adapted to the respective television standard by phase switching.

Preferably, the image memory is preceded by an analog-to-digital converter which converts the video output signal into digital form without having previously split it up into luminance and chrominance components.

A further increase in the image quality is achieved by the development of the control circuit according to the invention according to claims 14 to 16 and by the development of the method according to the invention according to claim 21. The lighting device used to set the operating point of the image converter is switched off at least during the period of lack of light supply to the video camera. Thus, a complete constancy of the charge image is achieved during the respective period of the lack of light supply to the video camera. This makes it possible to read out the charge image at any time during the absence of light. This is particularly important if, for reasons of synchronization of the readout process of the charge image in order to generate the video output signal with the horizontal synchronization pulse of the video camera, it is necessary to carry out the readout process with different time intervals with respect to the time at which the light supply to the video camera ceases.

If the setting of an optimal working point of the image converter can be dispensed with, this can be achieved in an extremely simple manner according to claim 16 by switching off the lighting device indefinitely.

• Fig. 1 ein erstes Ausführungsbeispiel einer erfindungsgemäßen Steuerschaltung mit einer in einem Strahlengang einer Laufbild-Spiegelreflexkamera angeordneten Videokamera;
• Fig. 2 eine abgewandelte Ausführungsform der erfindungsgemäßen Steuerschaltung für eine in einem Strahlengang einer Laufbild-Spiegelreflexkamera angeordnete Videokamera;
• Fig. 3 eine zeitliche Signaldarstellung zum Erläutern der Funktionsweise der erfindungsgemäßen Steuerschaltung;
• Fig. 4 ein detailliertes Schaltungsdiagramm der erfindungsgemäßen Steuerschaltung;
• Fig. 5 ein Schaltungsdiagramm einer Farbaufbereitungsschaltung; und
• Fig. 6 ein Schaltungsdiagramm einer Steuerschaltung zum Steuern einer Grundbeleuchtung eines Bildwandlers der Videokamera.

Preferred embodiments of the present invention are explained in more detail below with reference to the accompanying drawings. Show it:

• Fig. 1 shows a first embodiment of a control circuit according to the invention with a video camera arranged in a beam path of a motion picture SLR camera;
• 2 shows a modified embodiment of the control circuit according to the invention for a video camera arranged in a beam path of a motion picture SLR camera;
• 3 shows a temporal signal representation for explaining the functioning of the control circuit according to the invention;
• Fig. 4 is a detailed circuit diagram of the control circuit according to the invention;
• Fig. 5 is a circuit diagram of a color editing circuit; and
• Fig. 6 is a circuit diagram of a control circuit for controlling a basic lighting of an image converter of the video camera.

First, reference is made to FIG. 1. A motion picture SLR film recording camera 1 known per se has a lens 2 through which a beam path 3 extends from the object to be recorded into the camera. The beam path 3 is alternately passed through a mirror diaphragm 5 rotating about an axis 4 to a film 6 to be exposed and is switched into a viewfinder beam path 9. Part of the radiation entering the finder beam path is emitted by a partially transparent mirror surface 10 to a viewfinder 7, while the radiation residue 11 reaches a video camera 12. An image of the object to be recorded generated by the optics 2 via the mirror diaphragm 5 lies in a plane 8. The optical components for transmitting this image present in the plane 8 into the eyepiece of the finder 7 are known in the prior art and therefore do not need to be described further. Likewise, no description of the mode of operation and the details of the film camera 1 known per se in the prior art is required.

The video camera 12 has the usual structure known in the prior art. As an image converter, it usually has a vidicon picture tube, in which the incident light is converted into a charge image that is read out line by line. Likewise, the video camera can have a so-called "solid state imager" as an image converter element, which also converts the incident radiation into a charge image.

The position of the mirror diaphragm 5 is detected by a position sensor 13, the output signal 14 of which is fed to a control circuit 15. The control circuit 15 is connected to a control input 17 of the video camera 12. Furthermore, the control circuit 15 is connected to a control input of an image memory 21, with which a video output signal of the video camera 12 can be stored. The image memory 21 is connected on the output side to a video tape recorder 23 and to two monitors 24.

The mode of operation of the control device shown in FIG. 1 is explained in more detail below with reference to the temporal signal curves shown in FIG. 3. The Position sensor 13 generates a pulse chain with a pulse frequency that corresponds to the rotational frequency of the mirror diaphragm 5. From this output signal of the position sensor 13, the control device 15 forms a signal 16a (FIG. 3d), which has a high logical potential during each time period 16 (FIG. 3a), during which the beam path 3 is deflected from the mirror diaphragm 5 to the video camera 12 . The signal 16a, which is present at the control input 17 of the video camera 12, generates a blocking potential at a control grid of the Vidikon tube (not shown), which prevents the charge image from being read out. Thus, the deleting reading of the charge image for generating the video output signal during the light supply to the video camera 12 is prevented.

3b shows a pulse chain 18, which represents the video clock of the video camera 12. The video clock 18 represents the respective starting point in time when a charge field is read out in the absence of the blocking signal 16a. A pulse in the video clock 18 which occurs during the period of presence of the signal 16a preventing the charge image from being read out does not lead to the charge image being read out.

3c shows the charge profile of a pixel of the charge image of the Vidikon tube. The charge increases continuously during the supply of light from the object to the video camera, while the charge remains constant after the supply of light is interrupted. Regardless of the selected readout point in time, which is represented by a downward-pointing arrow, within the time period in which there is no light supply to the video camera, the video output signal remains constant.

The image memory 21, the construction of which in the state of the Known technology has a capacity of a field or an image. After a partial image or image has been taken over by the video camera 12 under the control of the takeover signal 20, the image memory 21 interrupts the storage of the video output signal. The next image or partial image is only taken over by the video camera when the takeover signal is generated again. The takeover signal 20 for the image memory 21 can be generated by inverting the signal 16a preventing the reading of the charge image.

On the output side, the image memory 21 can be read out at a frequency which corresponds to the field repetition frequency of a desired television standard. The image memory 21 thus enables frequency decoupling of the transfer of the charge images from the video camera 12 to the image memory and the reading out of the image memory at its output 22.

The video signal present at the output 22 of the image memory 21 is fed to the video tape recorder 23 and the monitors 24.

A modified embodiment of a control circuit for a video camera, which is further improved compared to the embodiment shown in FIG. 1, is shown in FIG. 2. Identical or similar parts of the exemplary embodiments shown in FIGS. 1 and 2 are denoted by the same reference symbols, so that a repeated description of these parts can be omitted.

The video camera 12 is connected to three inputs of the control circuit 15 via three lines. By means of these lines, the video camera 12 supplies the control circuit 15 with a horizontal synchronization signal 41, a color carrier signal 42 and a vertical synchronization signal 43.

The control circuit 15 supplies the video camera with a vertical reset signal 45 in addition to the signal 16a preventing the charge image from being read out.

The video camera 12 feeds the video output signal to an analog-to-digital converter, which converts the video output signal in its complete form, i.e. H. converted into digital form without subdivision into luminance signals and chrominance signals. Likewise, the analog-to-digital converter 31 converts output signals of a time and control signal generator 60 which, on the one hand, attaches optical time and control marks to the film 6 and, on the other hand, superimposes corresponding time and control marks on the video output signal of the video camera 12, so that in the case of a later one Film editing a simple assignment of a video film section to a specific film image is possible.

The output signal of the analog-digital converter 31 is fed to a first changeover switch 32, which is connected to two partial areas 21a, 21b of the image memory 21, in each of which a partial image can be stored. The subareas 21a, 21b of the image memory 21 are connected to a second, external switch 33 with a common image memory output 50. The first changeover switch 32 and the second changeover switch 33 are controlled by the control circuit 15 via a control signal line 34 in such a way that a changeover takes place each time a partial image is read out from the video camera and that the partial area 21a, 21b of the image memory 21 currently connected on the input side to the video output 19 switched off on the output side from the common image memory output 50. Thus, the video output signal can only be stored in that sub-area 21b from which no sub-picture can be read out at the moment, and on the other hand, the read-out only from one Sub-area 21a can be made in which no sub-picture can be stored at the moment.

The video camera 12 operates in such a way that the color carrier phase of successive partial images read from it remains constant. A color processing circuit 35 connected to the output 50 of the image memory 21a, 21b carries out a phase rotation of the color carrier signal for every second field read out in accordance with the television standard desired in each case. Typically, the color carrier phase is rotated at the reading of each second sub-image 180 ^0th

As far as the generation of the vertical reset signal for the video camera 12 and the control of the image memory 21 by means of a memory control signal 30 is concerned, reference is made to the following explanation of the circuit according to FIG. 4.

With regard to the mode of operation of the color processing circuit 35, reference is made to FIG. 5.

During the period of interruption of the light supply to the video camera, the control circuit 15 switches off the basic lighting of the video camera 12. The operation of the control circuit 15 in this regard is explained with reference to FIG. 6.

As shown in Fig. 4, the control circuit 15 includes a monostable multivibrator 40 which forms a pulse from the pulse-shaped output signal 14 generated by the position sensor 13, the pulse duration of which is greater than the distance between two pulses of the horizontal synchronization signal 41 of the video camera 12. The output signal the monostable multivibrator 40 is fed to a first input of an AND gate 57, to which the horizontal synchronization signal 41 and the color carrier 42 are also fed. By combining these three signals, a vertical reset pulse is generated at the output of the AND gate 57, the duration of which is determined by a further monostable multivibrator 61. This vertical reset pulse 45 serves to reset the video clock in order to read out the charge image starting with the first image point of the charge image.

The vertical synchronization signal 43 of the video camera 12 is halved in frequency by means of a D flip-flop 62 and a reset input 44 of a second D flip-flop 63 is supplied. The vertical reset signal 45 is fed to the clock input of the second flip-flop 63. At the inverted output of the second flip-flop 63 there is the signal for preventing the charge image 16a from being read out, as well as a further signal 30 with which an address control of the memory 21 is reset. This ensures that the charge image of the video camera 12 read out starting with the first pixel of the partial image is stored in the appropriate order in the partial area 21a, 21b of the image memory 21.

The color processing circuit 35 shown in FIG. 2 is explained in more detail below with reference to FIG. 5. The color processing circuit 35 consists of a filter circuit 51, to which the output signal 50 of the image memory 21 is supplied. The filter circuit 51, which is known per se in the prior art, separates the output signal into the chrominance signal 52 and into the luminance signal 53. The chrominance signal 52 is applied to a first pole of a switch 58 via an amplifier 64. Furthermore, the chrominance signal 52 is fed to an inverter 65, which has a second pole of the changeover switch 58 on the output side connected is. The luminance signal 53 is amplified by means of an amplifier 66 and fed to a node 67, to which the output of the switch 58 is also connected.

The vertical synchronization signal 43 of the video camera 12 is divided via a D flip-flop 68 into an output signal 48 of half the frequency. This output signal 48 is again divided in terms of frequency by means of a further D flip-flop 69. The inverting output of the flip-flop 69 controls the switch 58 for the chrominance signal 52. The output signal of the switch 58 is fed to the node 67 together with the amplified luminance signal 53 and the output signal of the flip-flop 68. The potential of the node is raised via an amplifier 70 connected downstream of the node and serves as a video signal for driving the downstream tape recorder 23 or the downstream monitor 24 (FIG. 2).

FIG. 6 shows a control circuit for switching an illumination device 56 on and off, which is used to generate basic lighting of the image converter inside the camera for setting the operating point of the image converter. The lighting device is provided as a light emitting diode 56 in conventional video cameras 12 working with Vidikon tubes. The signal 16a preventing the reading of the charge pattern is applied to a transistor switch via a pulse shaper stage 54, which is connected in parallel to the light-emitting diode 56. The light-emitting diode 56 is thus switched off while the signal 16a preventing the charge image from being triggered is present.

In deviation from the circuitry shown in FIG. 6, the control of the lighting device 56 can be directly medium of the output signal of the position sensor 13 are made. It only has to be ensured that the lighting device 56 is switched off at least during the time during which the light supply to the video camera 12 is interrupted.

Without optimizing the working point of the image converter, the basic lighting of the image converter can also be switched off indefinitely. In this case too, the lighting device is prevented from causing a change in the charge state of the charge image during the period of the interruption of the light supply to the video camera. Due to the constant charge level achieved during the period of the interruption of the light supply to the video camera, the charge image can be read out at any time within this time period, that is to say preferably in synchronization with the horizontal synchronization pulse of the video camera 12 and the signal from the position sensor 13 and the color carrier signal.

Although the control circuit according to the invention is preferably used where a video camera is arranged in a beam path of a motion picture SLR camera, which is periodically interrupted by a movable mirror diaphragm, the control circuit according to the invention can also be used wherever there is a periodically interrupted light supply to the video camera or where an object illuminated with strongly fluctuating brightness is to be recorded with a video camera.

Claims (21)

1. Control circuit (15) for a video camera (12), with which a charge image of an object to be recorded can be generated, which is at least partially deleted when the charge image is read out to generate a video output signal of the video camera (12),
characterized that the control circuit (15) has a signal source (13) whose output signal represents the presence and absence of light from the object to be recorded to the video camera (12), that the control circuit (15) is connected to an input (17) of the video camera (12) and this feeds a signal (16a) preventing the reading of the charge image at least during the period during which the output signal of the signal source (13) is present Represents light supply. 2. Control circuit (15) for a video camera (12) according to claim 1, characterized in that that an electronic image memory (21) is provided which is connected to the video camera (12), that the control circuit (15) is connected to a control input of the image memory and supplies it with a takeover signal (20) for taking over the charge image by storing the video output signal if the output signal of the signal source (13) represents the lack of light supply. 3. Control circuit (15) for a video camera (12) according to claim 2, characterized in that that the storage capacity of the image memory (21) corresponds to a field or an image, and that the image memory (21) is designed in such a way that it interrupts the storage of the video output signal of the video camera (12) triggered by the takeover signal as soon as a complete field or image is stored in the image memory (21) and that it starts the storage again, as soon as the takeover signal is fed to him again. 4. Control circuit (15) for a video camera (12) according to one of claims 1 to 3, characterized in that
that the signal source is a photoelectric element arranged in the beam path of the video camera (12). 5. Control circuit (15) for a video camera (12) according to one of claims 1 to 3, wherein the video camera (12) is arranged in a beam path of a motion picture reflex camera (1), which periodically alternates from a movable mirror diaphragm (5) a film to be exposed and directed to the video camera (12) so that the light supply to the video camera (12) is periodically interrupted,
characterized ,
that the signal source is a position sensor (13) whose output signal represents the position of the mirror diaphragm (5). 6. Control circuit (15) for a video camera (12) according to one of claims 1 to 5, characterized in that
that the takeover signal (20) for the image memory (21) is the inverted signal with respect to the signal (16a) preventing the reading of the charge image. 7. Control circuit (15) for a video camera (12) according to one of claims 3 to 6, characterized
that the output signal generated by the signal source (13) is fed to a monostable multivibrator (40) provided in the control circuit (15) which, when the output signal occurs, has a pulse with a pulse duration exceeding the time interval between two horizontal pulses of the horizontal synchronization signal of the video camera (12) generated, and
that the output signal of the flip-flop (40) with the horizontal synchronization signal of the video camera (12) via a AND gate (57) is linked to a vertical reset signal for the video camera (12). 8. Control circuit (15) for a video camera (12) according to claim 7, characterized in that
that the AND gate (57) is also supplied with a color carrier signal (42) from the video camera (12) for logical combination with the output signal of the monostable multivibrator (40) and the horizontal synchronization signal to form the vertical reset pulse. 9. Control circuit (15) for a video camera (12) according to claim 7 or 8, characterized in that
that the takeover signal (20) and the reading of the charge image preventing signal (16a) are derived from the output signal of the AND gate. 10. Control circuit (15) for a video camera (12) according to one of claims 2 to 9, characterized in that that the image memory (21) is subdivided into partial areas (21a, 21b) into which the partial images can be stored and from which these partial images can be read out, that the image signal inputs of each section (21a, 21b) of the image memory (21) can be connected to the video output (19) of the video camera (12) via a first switch (32), that the image signal outputs of each section (21a, 21b) of the image memory (21) can be connected to a common image memory output via a second changeover switch (33), and that the control circuit (15), the changeover switch (32, 33) Art controls that the portion (21a, 21b) of the image memory (21) currently connected on the input side to the video output (19) is switched off on the output side of the common image memory output. 11. Control circuit (15) for a video camera (12) according to claim 10, characterized in that
that the control circuit (15) actuates the changeover switch (32, 33) each time a signal preventing the reading of the charge pattern occurs. 12. Control circuit (15) for a video camera (12) according to claim 10 or 11, characterized in that that the video camera (12) generates a color carrier signal, the phase of which is invariable compared to that of the horizontal and vertical synchronization signal, and that the common image memory output at the second switch (33) is connected to a color conditioning circuit (35) which switches the phase of the color carrier signal under the control of the control device (15) according to a color signal phase sequence for partial images of a desired color television standard. 13. Control circuit (15) for a video camera (12) according to one of claims 2 to 12, characterized in that
that an analog-digital converter (31) between the video signal output of the video camera (12) and the input of the image memory (21) is switched on. 14. Control circuit (15) for a video camera (12) according to one of claims 1 to 13, with a Grundbe Illumination of an image converter of the video camera (12) for setting a working point of the illumination device producing the image converter, characterized in that
that the control circuit (15) is connected to the lighting device and switches it off at least during the period during which the output signal of the signal source (13) represents the lack of light supply. 15. Control circuit (15) for a video camera (12) according to claim 14, characterized in that
that the control circuit (15) switches off the lighting device by means of the signal preventing the reading of the charge image. ₁ 6. Control circuit (15) for a video camera (12) according to one of claims 1 to 13, with a basic illumination of an image converter of the video camera (12) for setting an operating point of the image converter generating lighting device (56), characterized in that
that the lighting device (56) can be switched off indefinitely. 17. Method for controlling a video camera (12) with the method steps generating a charge image of an object to be recorded and generating a video output signal by reading out the charge image at least partially erasing the charge image,
characterized by the process steps the detection of a periodically present or missing light supply from the object to be recorded to the video camera (12) and preventing the charge image from being read out at least while the light is being supplied from the object to be recorded to the video camera (12). 18. The method according to claim 17, characterized by the method step
reading the charge image and storing the video output signal in the absence of light. 19. The method according to claim 18, characterized in that the storing of the video output signal is interrupted as soon as a field is stored, and that the interrupted storage is resumed as soon as a lack of light is determined again. 20. The method according to claim 18 or 19, characterized in that
that a vertical reset of a time control for the video output signal and an address control for the storage in the absence of light is carried out in synchronization with a horizontal synchronization signal and a color carrier signal of the video camera. 21. The method according to any one of claims 17 to 20, characterized by
the step of switching off a basic lighting device of the video camera in the absence of light from the object to be recorded to the video camera (12).

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